Chemical enhancement effects on protoporphyrin IX surface‐enhanced Raman spectra: Metal substrate dependence and a vibronic theory analysis

McNeely, James; Ingraham, H.; Premasiri, W. Ranjith; Ziegler, L. D.

doi:10.1002/jrs.6009

Cited by 9 publications

(6 citation statements)

References 89 publications

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“…The amplification of the Raman signal is attributed to two effects: the chemical factor, which consists in the chemisorption of the analyte in the noble metal nanostructure where an adsorbate-metal complex is formed, amplifying the molecular orbitals of the analyte caused by an interaction with the conduction bands of the metal [17][18][19], and the electromagnetic effect, which consists in an increase of the local electric field caused by the polarization in the metal nanoparticles [20] and the interaction with the Raman signal scattered by the re-radiation process [21].…”

Section: Introductionmentioning

confidence: 99%

Retracted: Zeptomolar detection of 4-aminothiophenol by SERS using silver nanodendrites decorated with gold nanoparticles

Ceballos¹,

López²,

Morquecho³

et al. 2021

Nanotechnology

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In the present work we report a simple, fast, reproducible and cheap methodology for SERS substrate fabrication of silver dendritic nanostructures (prepared by electrodeposition) decorated with gold nanospheres by electrophoretic deposition. This is the first report where a metal dendritic nanostructure has been decorated with another type of metal nanoparticles by this technique. The decorated nanostructures were used directly as SERS substrate using 4-aminothiophenol (4-ATP) as analyte. The objective of the decoration is to create more hot-spots in order to detect the analyte in a lower concentration. Decorated nanodendrites had a detection limit one million times lower than bare silver nanodendrites and all the substrates showed an increase in the Raman intensity at concentrations below 1 nM; because this concentration corresponds to the threshold for the formation of a monolayer resulting in a triple mechanism of intensity increase, namely electric field, chemical factor and hot-spots. 4-ATP was detected in zeptomolar concentration, which is below 1 ppq, corresponding to an analytical enhancement factor (AEF) in the order of 1015.

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Section: Introductionmentioning

confidence: 99%

Retracted: Zeptomolar detection of 4-aminothiophenol by SERS using silver nanodendrites decorated with gold nanoparticles

Ceballos¹,

López²,

Morquecho³

et al. 2021

Nanotechnology

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“…Calculations reveal that the vibronic coupling resulting from the new low‐lying metal to heme π* charge transfer bands of the physi‐adsorbed analyte‐surface complex is metal dependent and accounts for the different relative 785 nm SERS intensities on Au and Ag apart from any additional orientational effects. [ 32 ] The observed pattern of relative intensities in these 785 nm SERS spectra are different than those seen for SERRS excited in the Soret or α , β band regions. [ 37–44 ]…”

Section: Resultsmentioning

confidence: 97%

“…It was previously established for hemoglobin at least, that the 785‐nm SERS spectrum in 50% acetic acid on Au and on Ag substrates have distinct patterns of relative intensities due, in part, to the metal specificity of 785‐nm chemical enhancement effects. [ 28,32 ] The studies describe here will address whether such metal surface dependent differences extend to all the heme proteins and solvent environments observed here.…”

Section: Introductionmentioning

confidence: 95%

“…In addition to the high level of sensitivity previously demonstrated for the SERS spectra of dried blood via HAc extraction and transfer to the SERS substrates, the corresponding robust 785-nm SERS signature of dried blood on the Au and Ag SERS substrates, that is, the pattern of relative vibrational intensities, was shown to be nearly completely different on the two metals. [28,32] Figure 2 shows the normalized 785 nm excited SERS spectrum of myoglobin in 50% acetic acid (HAc) on Au and Ag substrates. These are virtually identical (vide infra) to the 785 nm excited SERS spectra of dried blood, red blood cells, and hemoglobin shown previously.…”

Section: Myoglobin Hematin In 50% Acetic Acid Sers Spectramentioning

confidence: 99%

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NIR surface enhanced Raman spectra of biological hemes: Solvation and plasmonic metal effects

Ingraham

Premasiri

Ziegler

2021

J Raman Spectroscopy

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Surface enhanced Raman spectra (SERS) excited at 785 nm are reported for hemoglobin, myoglobin, two heme B proteins, and cytochrome c, a heme C protein, solubilized in a variety of solvent systems and then placed on Au and Ag substrates. These solvent environments include H2O pH 7.4, HCl/water pH 2, HCl/50% ethanol pH 2, 50% acetic acid and the organic layer of a pH 2 HCl/butanone mixture. To obtain the most intense SERS spectra of heme B proteins (Mb and Hb) it is not sufficient to be in a low pH (pH ~ 2) denaturing environment. A hydrophobic solvent component is additionally required in order to efficiently solubilize the cleaved heme moiety and consequently observe intense SERS spectra indicative of these heme B proteins. Although both heme B proteins exhibit virtually identical, metal (Au, Ag) specific SERS spectra, Cyt c is much weaker in the low pH environments and only displays a Ag‐like SERS spectrum on both metals indicating that this heme C protein is not cleaved in any of these solvation environments. The strong SERS signals of hemoglobin and myoglobin are due to hemin and ferric acetate heme formed in pH 2 HCl/ethanol and pH 2/50% acetic acid solutions respectively. SERS vibrational features confirm oxidation state, coordination number and ligands. SERS signals due to globin protein aggregation effects are reduced in low pH solvent systems with polarities lower than pure water. These results confirm the mechanism of a successful acetic acid protocol previously developed for the highly sensitive SERS detection of dried blood for forensic applications and indicate how it may be further improved to achieve even higher SERS sensitivity for heme protein detection.

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“…For details of the changes made between the two works, please see the supplementary data. an adsorbate-metal complex is formed, amplifying the molecular orbitals of the analyte caused by an interaction with the conduction bands of the metal [17][18][19], and the electromagnetic effect, which consists in an increase of the local electric field caused by the polarization in the metal nanoparticles [20] and the interaction with the Raman signal scattered by the re-radiation process [21].…”

Section: Introductionmentioning

confidence: 99%

Attomolar detection of 4-aminothiophenol by SERS using silver nanodendrites decorated with gold nanoparticles

et al. 2022

View full text Add to dashboard Cite

In the present work we report a simple, fast, reproducible and cheap methodology for SERS substrate fabrication of silver dendritic nanostructures (prepared by electrodeposition) decorated with gold nanospheres by electrophoretic deposition. This is the first report where a metal dendritic nanostructure has been decorated with another type of metal nanoparticles by this technique. The decorated nanostructures were used directly as SERS substrate using 4-aminothiophenol (4-ATP) as analyte. The objective of the decoration is to create more hot-spots in order to detect the analyte in a lower concentration. Decorated nanodendrites had a detection limit one million times lower than bare silver nanodendrites and all the substrates showed an increase in the Raman intensity at concentrations below 1 nM; because this concentration corresponds to the threshold for the formation of a monolayer resulting in a triple mechanism of intensity increase, namely electric field, chemical factor and hot-spots. 4-ATP was detected in attomolar concentration, which is below 1 ppq, corresponding to an analytical enhancement factor (AEF) in the order of 1015.

show abstract

Chemical enhancement effects on protoporphyrin IX surface‐enhanced Raman spectra: Metal substrate dependence and a vibronic theory analysis

Cited by 9 publications

References 89 publications

Retracted: Zeptomolar detection of 4-aminothiophenol by SERS using silver nanodendrites decorated with gold nanoparticles

Retracted: Zeptomolar detection of 4-aminothiophenol by SERS using silver nanodendrites decorated with gold nanoparticles

NIR surface enhanced Raman spectra of biological hemes: Solvation and plasmonic metal effects

Attomolar detection of 4-aminothiophenol by SERS using silver nanodendrites decorated with gold nanoparticles

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